OTA-BASED NEURAL-NETWORK ARCHITECTURES WITH ON-CHIP TUNING OF SYNAPSES

We propose and analyze analog VLSI implementations of neural networks in which both the neural cells and the synapses am realized using Oper ational Transconductance Amplifiers (OTAs). These circuits have inhere nt advantages of immunity to noise, very high input/output impedances, differential architecture with automatic inversion, and density. An e fficient on-chip technique for weight adaptation and for adjusting the gain of OTA-based neurons is proposed. Power and area requirements ar e obtained. These building blocks can be used to efficiently construct several types of networks including Hopfield networks, Boltzmann mach ines and cellular networks. Circuit simulations using MTIME show that small Hopfield memories converge in about a musec.